KR20130019872A - Method of non-destructive test using impedance analysis technique - Google Patents

Abstract

PURPOSE: A non-destructive inspection method using impedance analysis technique for inspecting material properties of a metallic part is provided to perform a non-destructive inspection of a product by using the impedance analysis technology by a non-contact mode on a real time basis. CONSTITUTION: A non-destructive inspection method using impedance analysis technique for inspecting material properties of a metallic part is as follows. An alternating current for generating a magnetic field in a sensor unit is supplied so that a primary magnetic field is generated around the sensor unit. An eddy current is generated by moving an inspection object close to the sensor unit. A secondary magnetic field opposite to the primary magnetic field is generated by the eddy current. Signals with respect to an overlapped result of the primary and secondary magnetic fields are sorted per a multi-frequency so that the sensor unit collects the signals. The unnecessary signals are removed from the collected signals by using signal processing software so that the necessary signals are separated and analyzed. An analysis result is displayed on a display unit by an interface form for a user. [Reference numerals] (AA) Start; (BB) Receiving heat-treatment data; (CC,HH,MM) No; (DD) Confirming data; (EE,II,OO) Yes; (FF,KK,QQ,RR) End; (GG) Confirming an operation; (JJ) Displaying a position on a data storage chart; (LL) Determining quality; (NN) Good; (PP) Bad

Description

Non-destructive Test Using Impedance Analysis Technique for Metal Component Material Using Impedance Analysis Technique

The present invention relates to a non-destructive testing method of the physical properties of metallic components, more specifically, by using an impedance analysis technology that reacts according to the metal properties in the magnetic field, the non-destructive testing of the physical properties of the product in a real-time non-contact method in the component material production line It is equipped with real-time, noise and environmental resistance required at the production site of parts and materials, and it uses automated analysis technology with enhanced convenience to make it easier for users to discriminate the quantity of inspection targets. The present invention relates to a method of nondestructive testing of metallic part material properties using impedance analysis technology, which is linked to management systems such as ERP.

The technology of inspecting products in the parts production line is largely classified into destructive inspection method and non-destructive inspection method. Among them, the destructive method is a method for monitoring a process by sampling, and a general inspection is performed in real time offline, while the non-destructive inspection method is mainly used to determine whether a product is defective or not. Perform a full inspection. In addition to Korea, many countries around the world, through free trade agreements (FTAs), are in direct competition with each other. The demand for technology for non-destructive full-scale inspection of parts materials online is also increasing.

In general, the fracture inspection method, which is conventionally performed on welded metal materials, separates by applying a physical force to two joined materials, and performs a separation test that estimates the welding state by the force required for the separation. There was also a time-consuming problem. In addition, in the case of such a destruction test, since the selected sample is destroyed during the inspection process, there is a problem in that an economic loss occurs as the product selected for inspection is discarded after the inspection and the inspection is performed.

In addition, the non-destructive inspection equipment system conventionally applied to the internal inspection of the human body, civil engineering, or building equipment has a problem that it is difficult for a non-expert to satisfy the experimental conditions such as the angle and distance between the probe and the inspection object. As a result of the inspection results, it is difficult to be used in many small and medium-sized companies because a separate data decryption ability is required to determine whether there is a defect in the inspection object. In addition, it was not easy to immediately use for the determination of defects of metallic component materials used in various processes.

The present invention has been made to solve the above problems, a method for non-destructive inspection of the physical properties of the product in a real-time non-contact method in the parts material production line using the impedance analysis technology that reacts according to the metal properties in the magnetic field In providing.

Another object of the present invention is to use the automated analysis technology that has enhanced convenience for the user to easily determine whether the target of the inspection target, while having the real-time, noise resistance, environmental resistance required at the production site of the parts and materials In addition, the analysis is to provide a non-destructive testing method for the properties of metallic component materials using impedance analysis technology, which is linked to the management system such as ERP.

CLAIMS 1. A method for nondestructive inspection of physical properties of a metallic component material by using a real-time non-contact method, comprising: a first step of supplying an alternating current for generating a magnetic field to a sensor part to generate a primary magnetic field near the sensor; A second step of generating an eddy current by approaching a test object to the sensor unit, and generating a secondary magnetic field opposite to the primary magnetic field by the eddy current; A third step of dividing a signal for the superimposed result of the primary magnetic field and the secondary magnetic field by multiple frequencies and collecting the signals by the sensor unit; A fourth step of removing unnecessary signals from the signals collected for each of the multiple frequencies through a signal processing software module mounted in a signal processing application program and separating only necessary signals, respectively, and analyzing the separated signals; And a fifth step of outputting the analyzed result to the display unit in an interface form to the user.

In the fourth step, the signals collected for each of the multiple frequencies are divided into amplitude and phase signals using an impedance analysis technique, and the values of the amplitude and phase signals separated for respective frequencies are plotted and plotted in a chart of xy coordinates. Aggregating the x, y values of the frequency-specific chart, respectively, and synthesizing them into a single coordinate of the comprehensive chart, wherein the fifth step includes a line for determining the quantity of good and low based on the property data of the parts. Non-destructive testing of metallic component material properties using an impedance analysis technology, characterized in that the user can easily determine whether the target of the inspection object, according to whether or not the single coordinate of the comprehensive chart is displayed inside the range line. It is a way. In addition, the signal processing application program can be linked to the resource management system.

According to the present invention as described above, by using the impedance analysis technology that reacts according to the metal properties in the magnetic field, by real-time contactless non-destructive inspection of the physical properties of the product in the component material production line, real-time properties, job resistance required in the production site of the component material The effect of satisfying voice and environmental resistance can be expected.

Another effect of the present invention, through the various functions of the signal processing application program, the user interface to the one-dimensional signal that is difficult to read useful to use, and the utilization of such a great use, such as interworking with the upper resource management system There is a rising aspect.

1 is a block diagram of a system according to the non-destructive testing method of the present invention.
Figure 2 is a flow chart showing the third, fourth steps according to the non-destructive testing method of the present invention.
3 is an exemplary diagram of an interface represented by a single coordinate by combining all the hardness values of the signals collected for each of the multiple frequencies in the non-destructive testing method of the present invention.
Figure 4 is a network diagram of a system according to the non-destructive testing method of the present invention.
5 is a software configuration diagram of a system according to the non-destructive testing method of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention.

1 is a block diagram of a system according to the non-destructive testing method of the present invention.

Referring to Figure 1, the non-destructive testing method of the metallic component material properties using the impedance analysis technique according to the present invention is performed in a total of five steps. Supplying an alternating current for generating a magnetic field to the sensor unit, thereby generating a primary magnetic field near the sensor; A second step of generating an eddy current by approaching a test object to the sensor unit, and generating a secondary magnetic field opposite to the primary magnetic field by the eddy current; A third step of dividing a signal for the superimposed result of the primary magnetic field and the secondary magnetic field by multiple frequencies and collecting the signals by the sensor unit; A fourth step of removing unnecessary signals from the signals collected for each of the multiple frequencies through a signal processing software module mounted in a signal processing application program and separating only necessary signals, respectively, and analyzing the separated signals; And a fifth step of outputting the analyzed result to the display unit in an interface form to the user.

At this time, the metallic component material which performs the non-destructive inspection according to the present method is relatively easy to be a shaft type material having a cylindrical shape. In addition, although it is determined whether crack inspection is applicable depending on the thickness of the metal part, it is generally possible to perform physical property test such as heat treatment and cracks on a metal part material of 10 mm or less. In case of cracks, the thickness of the component material determines whether crack inspection is possible because it is seriously affected by the penetration depth of the eddy current signal. However, heat treatment and shape inspection can be applied to various fields in addition to automobile parts.

The signal flow of the eddy current hardware supplies AC current to the sensor unit to create a magnetic field, and generates a primary magnetic field around the sensor unit. When an eddy current is generated near the inspection object, the secondary magnetic field generated by the eddy current becomes the primary. Form a magnetic field opposite to the magnetic field. Because of this, due to mutual interference, the primary magnetic field and the secondary magnetic field overlap, the result is different depending on the physical properties of the test object. By separating and analyzing the amplitude and phase signals in the impedance plane, it is possible to observe various reactions to physical properties, and to analyze the phase and amplitude information to identify the degree of heat treatment in a non-contact manner.

On the other hand, it is necessary to generate a strong magnetic field in order to generate an eddy current in the inspection object, a current amplification circuit is required to generate a strong magnetic field. In general, it uses a current amplifying element to design a circuit that multiplies the voltage as well as double the current, and to amplify the magnetic field in the sensor twice as a technology of analog circuit to reduce the burden of voltage amplification in the ADC circuit. to be.

On the other hand, it is very important to determine the configuration of the sensor unit in the non-destructive inspection method of the metallic component material properties using the impedance analysis technology according to the present invention. When the item to be inspected is determined for the object to be inspected, it is determined which characteristic of the sensor is used to determine the test and the interpretation technique of the signal. In general, non-destructive testing technology is the application area is determined by the sensor unit, the sensor unit can be tested by clearly identifying the signal to be tested from the various signals.

In particular, the eddy current sensor has to satisfy various requirements in order to detect the small change in conductivity caused by the change in hardness among the physical properties of the inspection object. The standard configuration specification extracted from the test depends on the shape and composition of the magnetic material used in the manufacturing process as well as the circuit coil diameter, number of turns, the density of the coil during winding, the signal receiving circuit, and the amplification degree. It is preferable to refer.

FIG. 2 is a flowchart showing steps 3 and 4 according to the non-destructive testing method of the present invention. FIG. 3 is an interface showing a single coordinate by combining all the hardness values of signals collected for each of the multiple frequencies in the non-destructive testing method of the present invention. An illustration of the.

In the system according to the method of the present invention, the impedance technique is applied as the two-dimensional analysis technique in order to perform the analysis in the frequency domain as well as the analysis in the time domain. The change of the secondary magnetic field sensed by the sensor is a very weak signal, which can be obtained by a medium impedance of about 1V through sophisticated impedance matching and differential amplification. This is again amplified to several volts to perform AD conversion.

The conversion circuit for the AD conversion is composed of two AD conversion circuits for separating and converting the signal obtained from the sensor unit into phase and amplitude signals, each of which is projected onto the impedance plane through special processing and the signal is analyzed in the two-dimensional plane. It becomes possible.

As shown in FIG. 3, the signals collected for each of the multiple frequencies are separated into amplitude and phase signals using impedance analysis techniques, and the values of the amplitude and phase signals separated for respective frequencies are plotted in a chart of xy coordinates. . In this example screen, eight frequency channels are used.

Subsequently, x and y values of the frequency-specific charts are aggregated and synthesized into single coordinates of the comprehensive chart. The single coordinates are indicated by the points on the x-y coordinates of the lower part of FIG. 3. In the fifth step, the range line for determining the quantity of fire, which is determined based on the standard property data of the part, is displayed on the comprehensive chart. According to whether or not the single coordinates of the comprehensive chart are displayed inside the range line, the user can easily determine whether the inspection object is good or bad. If a single coordinate is located inside the range line of the rectangle, it can be determined that the test object has properties that do not deviate from the standard property data.

4 is a network configuration diagram of a system according to the non-destructive testing method of the present invention, Figure 5 is a software configuration diagram of the system according to the non-destructive testing method of the present invention.

4 and 5, the configuration of the signal processing application in the non-destructive testing method of the physical property of the metallic component material using the impedance analysis technique according to the present invention. In order to analyze the signal collected by the sensor unit, it is necessary to preprocess the noise-mixed raw signal and convert it into a data form for signal analysis. The signal processing application program expresses the result of signal analysis in the form of an interface that a human can easily recognize the preprocessed data on the monitor by using the technology of analyzing the data received from the sensor collected signal preprocessing module. The signal processing application program provides a user interface function, a hardware interworking function, and provides a function interworking with the production process management ERP of a company using the system according to the present invention. Therefore, the center of the system configuration of the present invention will be located.

The connection between the sensor unit and the monitoring terminal generally uses a LAN, and wireless connection using a wireless AP is also possible. In addition, the signal collected in the sensor unit is transmitted to the test terminal through a data cable, and then input to the signal processing application program for analysis, and outputs the result to the display unit in an interface form. At this time, according to the experiments of the applicant, it can be seen that a data cable generally leads to a good result using an RS232 model. In addition, the user's terminal configures the application program to run in various OS environments including Windows.

In addition, the interface configuration of the signal processing application program is largely divided into two functions, a business function and an ERP system function. Business functions include an operation window for displaying inspection details in real time, a hardness conversion table for inputting and managing the hardness of inspection details, and a communication setting function for managing equipment and communication settings. ERP system function has inspection history that can save inspection log file and inspection history that can search inspection history and check distribution chart. This is an example, and more menu configurations may be possible.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it is possible to make various modifications and variations without departing from the spirit and scope of the invention. Accordingly, the scope of the appended claims should include all such modifications and changes as fall within the scope of the present invention.

Claims (2)

In the method of non-destructive inspection of the physical properties of the metallic component material in a real-time non-contact method,
Supplying an alternating current for generating a magnetic field to the sensor unit, thereby generating a primary magnetic field near the sensor;
A second step of generating an eddy current by approaching a test object to the sensor unit, and generating a secondary magnetic field opposite to the primary magnetic field by the eddy current;
A third step of dividing a signal for the superimposed result of the primary magnetic field and the secondary magnetic field by multiple frequencies and collecting the signals by the sensor unit;
A fourth step of removing unnecessary signals from the signals collected for each of the multiple frequencies through a signal processing software module mounted in a signal processing application program and separating only necessary signals, respectively, and analyzing the separated signals; And
A fifth step of outputting the analyzed result to the display unit in the form of an interface to the user,
In the fourth step, the signals collected for each of the multiple frequencies are divided into amplitude and phase signals using an impedance analysis technique, and the values of the amplitude and phase signals separated for respective frequencies are plotted and plotted in a chart of xy coordinates. Aggregate the x, y values of each frequency chart and synthesize them into a single coordinate of the overall chart.
In the fifth step, the range of the amount of discrimination determined on the basis of the standard property data of the parts is displayed on the comprehensive chart, and according to whether a single coordinate of the comprehensive chart is displayed inside the range line, the user is inspected. Nondestructive testing method for the properties of metallic component materials using impedance analysis technology, characterized in that it is possible to easily determine the good or bad.
The method of claim 1,
The signal processing application program, the non-destructive inspection method of the physical properties of the metallic component material using the impedance analysis technology, characterized in that the interlock with the resource management system.

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